Your search keyword '"Zunino, Paolo"' showing total 7 results

1. Application of deep learning reduced-order modeling for single-phase flow in faulted porous media

Author

Ballini, Enrico, Formaggia, Luca, Fumagalli, Alessio, Scotti, Anna, and Zunino, Paolo

Published

2024

2. On the latent dimension of deep autoencoders for reduced order modeling of PDEs parametrized by random fields

Author

Franco, Nicola Rares, Fraulin, Daniel, Manzoni, Andrea, and Zunino, Paolo

Published

2024

3. Deep learning enhanced cost-aware multi-fidelity uncertainty quantification of a computational model for radiotherapy.

Author

Vitullo, Piermario, Franco, Nicola Rares, and Zunino, Paolo

Subjects

PROPER orthogonal decomposition, MONTE Carlo method, PARTIAL differential equations, MULTISCALE modeling, MICROCIRCULATION, DEEP learning

Abstract

Forward uncertainty quantification (UQ) for partial differential equations is a many-query task that requires a significant number of model evaluations. The objective of this work is to mitigate the computational cost of UQ for a 3D-1D multiscale computational model of microcirculation. To this purpose, we present a deep learning enhanced multi-fidelity Monte Carlo (DL-MFMC) method that integrates the information of a multiscale full-order model (FOM) with that coming from a deep learning enhanced non-intrusive projection-based reduced order model (ROM). The latter is constructed by leveraging on proper orthogonal decomposition (POD) and mesh-informed neural networks (previously developed by the authors and co-workers), integrating diverse architectures that approximate POD coefficients while introducing fine-scale corrections for the microstructures. The DL-MFMC approach provides a robust estimator of specific quantities of interest and their associated uncertainties, with optimal management of computational resources. In particular, the computational budget is efficiently divided between training and sampling, ensuring a reliable estimation process suitably exploiting the ROM speed-up. Here, we apply the DL-MFMC technique to accelerate the estimation of biophysical quantities regarding oxygen transfer and radiotherapy outcomes. Compared to classical Monte Carlo methods, the proposed approach shows remarkable speed-ups and a substantial reduction of the overall computational cost. [ABSTRACT FROM AUTHOR]

Published

2025

4. A three‐dimensional method for morphological analysis and flow velocity estimation in microvasculature on‐a‐chip.

Author

Rota, Alberto, Possenti, Luca, Offeddu, Giovanni S., Senesi, Martina, Stucchi, Adelaide, Venturelli, Irene, Rancati, Tiziana, Zunino, Paolo, Kamm, Roger D., and Costantino, Maria Laura

Subjects

TORTUOSITY, SHEARING force, FLUID flow, CONFOCAL microscopy, SHEAR walls, PHYSIOLOGICAL models

Abstract

Three‐dimensional (3D) imaging techniques (e.g., confocal microscopy) are commonly used to visualize in vitro models, especially microvasculature on‐a‐chip. Conversely, 3D analysis is not the standard method to extract quantitative information from those models. We developed the μVES algorithm to analyze vascularized in vitro models leveraging 3D data. It computes morphological parameters (geometry, diameter, length, tortuosity, eccentricity) and intravascular flow velocity. μVES application to microfluidic vascularized in vitro models shows that they successfully replicate functional features of the microvasculature in vivo in terms of intravascular fluid flow velocity. However, wall shear stress is lower compared to in vivo references. The morphological analysis also highlights the model's physiological similarities (vessel length and tortuosity) and shortcomings (vessel radius and surface‐over‐volume ratio). The addition of the third dimension in our analysis produced significant differences in the metrics assessed compared to 2D estimations. It enabled the computation of new indices, such as vessel eccentricity. These μVES capabilities can find application in analyses of different in vitro vascular models, as well as in vivo and ex vivo microvasculature. [ABSTRACT FROM AUTHOR]

Published

2023

5. A deep learning approach to Reduced Order Modelling of parameter dependent partial differential equations.

Author

Franco, Nicola R., Manzoni, Andrea, and Zunino, Paolo

Subjects

PARTIAL differential equations, ARTIFICIAL neural networks, ADVECTION-diffusion equations, DEEP learning, ORTHOGONAL decompositions, APPROXIMATION error, TOPOLOGICAL property

Abstract

Within the framework of parameter dependent Partial Differential Equations (PDEs), we develop a constructive approach based on Deep Neural Networks for the efficient approximation of the parameter-to-solution map. The research is motivated by the limitations and drawbacks of state-of-the-art algorithms, such as the Reduced Basis method, when addressing problems that show a slow decay in the Kolmogorov n-width. Our work is based on the use of deep autoencoders, which we employ for encoding and decoding a high fidelity approximation of the solution manifold. To provide guidelines for the design of deep autoencoders, we consider a nonlinear version of the Kolmogorov n-width over which we base the concept of a minimal latent dimension. We show that the latter is intimately related to the topological properties of the solution manifold, and we provide theoretical results with particular emphasis on second order elliptic PDEs, characterizing the minimal dimension and the approximation errors of the proposed approach. The theory presented is further supported by numerical experiments, where we compare the proposed approach with classical Principal Orthogonal Decomposition (POD)-Galerkin reduced order models. In particular, we consider parametrized advection-diffusion PDEs, and we test the methodology in the presence of strong transport fields, singular terms and stochastic coefficients. [ABSTRACT FROM AUTHOR]

Published

2022

6. A Deep Learning Approach Validates Genetic Risk Factors for Late Toxicity After Prostate Cancer Radiotherapy in a REQUITE Multi-National Cohort.

Author

Massi, Michela Carlotta, Gasperoni, Francesca, Ieva, Francesca, Paganoni, Anna Maria, Zunino, Paolo, Manzoni, Andrea, Franco, Nicola Rares, Veldeman, Liv, Ost, Piet, Fonteyne, Valérie, Talbot, Christopher J., Rattay, Tim, Webb, Adam, Symonds, Paul R., Johnson, Kerstie, Lambrecht, Maarten, Haustermans, Karin, De Meerleer, Gert, de Ruysscher, Dirk, and Vanneste, Ben

Subjects

DEEP learning, CANCER radiotherapy, RADIOTHERAPY treatment planning, SINGLE nucleotide polymorphisms, PROSTATE cancer patients, PROSTATE cancer, RADIOTHERAPY safety

Abstract

Background: REQUITE (validating pREdictive models and biomarkers of radiotherapy toxicity to reduce side effects and improve QUalITy of lifE in cancer survivors) is an international prospective cohort study. The purpose of this project was to analyse a cohort of patients recruited into REQUITE using a deep learning algorithm to identify patient-specific features associated with the development of toxicity, and test the approach by attempting to validate previously published genetic risk factors. Methods: The study involved REQUITE prostate cancer patients treated with external beam radiotherapy who had complete 2-year follow-up. We used five separate late toxicity endpoints: ≥grade 1 late rectal bleeding, ≥grade 2 urinary frequency, ≥grade 1 haematuria, ≥ grade 2 nocturia, ≥ grade 1 decreased urinary stream. Forty-three single nucleotide polymorphisms (SNPs) already reported in the literature to be associated with the toxicity endpoints were included in the analysis. No SNP had been studied before in the REQUITE cohort. Deep Sparse AutoEncoders (DSAE) were trained to recognize features (SNPs) identifying patients with no toxicity and tested on a different independent mixed population including patients without and with toxicity. Results: One thousand, four hundred and one patients were included, and toxicity rates were: rectal bleeding 11.7%, urinary frequency 4%, haematuria 5.5%, nocturia 7.8%, decreased urinary stream 17.1%. Twenty-four of the 43 SNPs that were associated with the toxicity endpoints were validated as identifying patients with toxicity. Twenty of the 24 SNPs were associated with the same toxicity endpoint as reported in the literature: 9 SNPs for urinary symptoms and 11 SNPs for overall toxicity. The other 4 SNPs were associated with a different endpoint. Conclusion: Deep learning algorithms can validate SNPs associated with toxicity after radiotherapy for prostate cancer. The method should be studied further to identify polygenic SNP risk signatures for radiotherapy toxicity. The signatures could then be included in integrated normal tissue complication probability models and tested for their ability to personalize radiotherapy treatment planning. [ABSTRACT FROM AUTHOR]

Published

2020

7. Nonlinear model order reduction for problems with microstructure using mesh informed neural networks.

Author

Vitullo, Piermario, Colombo, Alessio, Franco, Nicola Rares, Manzoni, Andrea, and Zunino, Paolo

Subjects

*DEEP learning, *PROPER orthogonal decomposition, *TRANSPORT theory, *BENCHMARK problems (Computer science), *COMPUTATIONAL physics, *LINEAR orderings

Abstract

Many applications in computational physics involve approximating problems with microstructure, characterized by multiple spatial scales in their data. However, these numerical solutions are often computationally expensive due to the need to capture fine details at small scales. As a result, simulating such phenomena becomes unaffordable for many-query applications, such as parametrized systems with multiple scale-dependent features. Traditional projection-based reduced order models (ROMs) fail to resolve these issues, even for second-order elliptic PDEs commonly found in engineering applications. To address this, we propose an alternative nonintrusive strategy to build a ROM, that combines classical proper orthogonal decomposition (POD) with a suitable neural network (NN) model to account for the small scales. Specifically, we employ sparse mesh-informed neural networks (MINNs), which handle both spatial dependencies in the solutions and model parameters simultaneously. We evaluate the performance of this strategy on benchmark problems and then apply it to approximate a real-life problem involving the impact of microcirculation in transport phenomena through the tissue microenvironment. • Numerical solution of microstructured problems imply high computational costs • Linear reduced order models do not capture the high-frequency modes of the solution • Deep learning-based approaches can be exploited to retrieve these intricate patterns • Our novel approach combines a non-intrusive reduced order model with a closure model • High dimensional data are handled leveraging on mesh-informed neural networks [ABSTRACT FROM AUTHOR]

Published

2024